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GHG Mitigation Potential in the Transport SectorGHG Mitigation Potential in the Transport SectorTransforming Transportation 2010Transforming Transportation 2010January 15, 2010January 15, 2010
presented bypresented by
Joanne R. PotterJoanne R. PotterCambridge Systematics, Inc.Cambridge Systematics, Inc.
Moving CoolerStudy Findings
Transportation leadership you can trust.
3
Transportation’s Contribution to U.S. GHGs
Source: Environmental Protection Agency (EPA). “Inventory of U.S. Greenhouse Gas Emissions and Sinks: 1990-2007,” April 2009, http://epa.gov/climagechange/emissions/usinventory.html.
U.S. GHG Emissions by End Use Economic Sector 2006
U.S. GHG Emissions Breakdown by Mode
Electricity Generation
33%
TransportationTransportation
28%28%
Residential
5%
Commercial
6%
Agriculture
8%
Industry
20%
Light-Duty Vehicles
59.3%
Heavy-Duty Vehicles
19.6%
OtherOther
2.0%2.0%
RailRail
2.7%2.7%
MarineMarine
4.9%4.9%
AircraftAircraft
11.5%11.5%
4
5
• U.S. Environmental Protection Agency
• U.S. Federal Highway Administration
• U.S. Federal Transit Administration
• American Public Transportation Association
• Environmental Defense
• ITS America
• Shell Oil
• Natural Resources Defense Council
• Kresge Foundation
• Surdna Foundation
• Rockefeller Brothers Fund
• Rockefeller Foundation
• Urban Land Institute
Analytic Team: Cambridge Systematics
Multiple Partners on Steering Committee:
6
Wide Range of Strategies Examined
Pricing, tolls, PAYD insurance, VMT fees, carbon/fuel taxes
Land use and smart growth
Nonmotorized transportation
Public transportation improvements
Regional ride-sharing, commute measures
Regulatory measures
Operational/ITS strategies
Capacity/bottleneck relief
Freight sector strategies
7
Focus of Analysis
Estimates GHG effectiveness and direct implementation costs
Not a full cost-benefit analysis – therefore not a complete basis for decisions
• GHG benefits only
• Direct agency monetary implementation costs
• Vehicle operating costs (savings) – fuel, ownership, maintenance, insurance
Political feasibility not assessed
Allows comparison to McKinsey Report findings on fuels and technology
8
1. Establish baseline
2. Select strategies and define parameters
3. Estimate the GHG reduction of each individual strategy
4. “Bundle” the strategies and examine the combined impacts
Analytic Approach
9
Assumptions for Baseline
Travel continues to grow
• VMT growth of 1.4% per year
• Transit ridership growth 2.4% / year
Fuel prices increase
• 1.2% per year, beginning at $3.70 / gallon in 2009*
Fuel economy improves steadily
• Light duty vehicles at 1.91% annually
• Heavy duty at 0.61%
*AEO high fuel price scenario
10
Moving Cooler Baseline to 2050
Note: This figure displays National On-Road GHG emissions as estimated in the Moving Cooler baseline, compared with GHG emission estimates based on President Obama’s May 19, 2009, national fuel efficiency standard proposal of 35.5 mpg in 2016. Both emission forecasts assume an annual VMT growth rate of 1.4 percent. The American Clean Energy and Security Act (H.R. 2454) identifies GHG reduction targets in 2012, 2020, 2030, and 2050. The 2020 and 2050 targets applied to the on-road mobile transportation sector are shown here.
National On-Road GHG Emissions (mmt)
0
200
400
600
800
1,000
1,200
1,400
1,600
1,800
2,000
2000 2005 2010 2015 2020 2025 2030 2035 2040 2045 2050
Study Baseline
American Clean Energy and Security Act 2020 Target (83% of 2005 emissions)
American Clean Energy and Security Act 2050 Target (17% of 2005 emissions)
Obama Administration Proposal
11
Moving Cooler Sensitivity Tests to 2050
High Fuel Price/Low VMT: Fuel prices increase dramatically, resulting in lower VMT and improved vehicle technology.
Low Fuel Price/High VMT: Lower fuel prices drive higher VMT growth and less investment in improved technology.
High Technology/High VMT: Technology progresses rapidly, leading to decreased driving cost and higher VMT.
National On-Road GHG Emissions (mmt)
0
200
400
600
800
1,000
1,200
1,400
1,600
1,800
2,000
2000 2005 2010 2015 2020 2025 2030 2035 2040 2045 2050
Study Baseline
American Clean Energy and Security Act 2020 Target (83% of 2005 emissions)
American Clean Energy and Security Act 2050 Target (17% of 2005 emissions)
Obama Administration Proposal
High Fuel Price, Low VMT
Low Fuel Price, High VMT
High Tech, High VMT
12
Strategy Parameters: 7 Area Types
Density /Level of Transit
Large urban Hi Low
Medium urban Hi Low
Small urban Hi Low
Non-urban
13
3 Deployment Levels per StrategyExample: Pricing Strategies Sample Parameters
Scope Intensity
Expanded current practice
Large urban areas
Peak hour at $0.45 / mile
More aggressive Large & medium urban areas
Peak hour at $0.69 / mile
Maximum effort Large, medium, & small urban areas
Peak hour at $0.69 / mile
1414
Findings: Individual Strategies
Individual strategies achieve varying levels of GHG reductions
• <0.5% to over 4.0% cumulatively to 2050
15
Example Findings: Individual Strategies
StrategyCumulative % GHG
reduction from baseline (2050)
VMT fees 0.4 - 4.9%
Speed limit reductions 1.7 - 3.5%
PAYD insurance 1.1 - 3.2%
Congestion pricing 0.8 – 1.8%
Eco-driving 1.0 – 2.6%
Land use/smart growth 0.2 - 2.0%
Urban Public Transit LOS/Expansion 0.3 - 1.1%
Employer based commute/parking pricing 0.4 - 1.7%
Operational and ITS improvements 0.3 – 0.7%
16
Strategy Bundles Illustrative Analysis
Low Cost
Near-Term/Early Results
Long-Term/Maximum Results
Land Use/Nonmotorized/
Public Transportation
System and Driver Efficiency
Facility Pricing
1717
Combinations of transportation strategies can achieve GHG reductions from transportation
• 4% to 18% GHG reduction from baseline* in 2050 (aggressive deployment, without economy-wide pricing)
• Up to 24% GHG reduction from baseline* in 2050 (maximum deployment, without economy-wide pricing)
These strategies complement the important reductions anticipated from fuel and technology advancements
Findings: Strategy Bundles
* Projections for on-road surface transportation GHG emissions
18
Range of Annual GHG Reductions of Six Strategy Bundles (Aggressive and Maximum Deployment)
1990 & 2005 GHG Emissions – Combination of DOE AEO data and EPA GHG Inventory data
Study – Annual 1.4% VMT growth combined with 1.9% growth in fuel economy
Aggressive Deployment Levels – Range of GHG emissions from bundles deployed at aggressive level
Maximum Deployment Levels – Range of GHG emissions from bundles deployed at maximum level
Total Surface Transportation Sector GHG Emissions (mmt)
0
200
400
600
800
1,000
1,200
1,400
1,600
1,800
2,000
1990 2000 2010 2020 2030 2040 2050
2005
1990
Note: This figure displays the GHG emission range across the six bundles for the aggressive and maximum deployment scenarios. The percent reductions are on an annual basis from the Study Baseline. The 1990 and 2005 baseline are included for reference.
Study Baseline
Aggressive Development Levels
Maximum Development Levels
4%
24%
1%3%
11%
17%18%
19
Economy-Wide Pricing
Mechanisms: Carbon pricing, VMT fee, and/or Pay As You Drive (PAYD) insurance
Strong economy-wide pricing measures added to bundles achieve additional GHG reductions
• Aggressive deployment: additional fee (in current dollars) starting at the equivalent of $0.60 per gallon in 2015 and increasing to $1.25 per gallon in 2050 could result in an additional 17% reduction in GHG emissions in 2050
Two factors would drive this increased reduction
1. Reduction in vehicle-miles traveled (VMT)
2. More rapid technology advances
20
Economy-Wide PricingTotal Surface Transportation Sector GHG Emissions (mmt)
0
200
400
600
800
1,000
1,200
1,400
1,600
1,800
2,000
1990 2000 2010 2020 2030 2040 2050
1990 & 2005 GHG Emissions – Combination of DOE AEO data and EPA GHG Inventory data
Study Baseline – Annual 1.4% VMT growth combined with 1.9% growth in fuel economy
Aggressive – GHG emissions from bundle deployed at aggressive level without economy wide pricing measures
2005
1990
Study Baseline
Aggressive
Economy-Wide Pricing
18%
35%
12%
30%
7%
19%
21
Direct Vehicle Costs and Costs of Implementing Strategy Bundles
Note: This figure displays estimated annual implementation costs (capital, maintenance, operations, and administrative) and annual vehicle cost savings [reduction in the costs of owning and operating a vehicle from reduced vehicle-miles traveled (VMT) and delay. Vehicle cost savings DO NOT include other costs and benefits that could be experienced as a consequence of implementing each bundle, such as changes in travel time, safety, user fees, environmental quality, and public health.
2008 Dollars (in Billions)2008 Dollars (in Billions)
$0
$20
$40
$60
$80
$100
$120
$140
$160
$180
$200
2010 2015 2020 2025 2030 2035 2040 2045
Vehicle Cost Savings
Implementation Costs
2050
22
Near-Term andLong-Range Strategies
Some strategies are effective in achieving near-term reductions, reducing the cumulative GHG challenge in later years
Investments in land use and improved travel options involved longer timeframes but would have enduring benefits
23
Scale of Implementation
Both national level and state/regional/local strategies are important
GHG reductions should be viewed relative to the scale of potential implementation
• While effect on national emissions may be modest, some strategies may be more beneficial at regional scales
24
Other Societal Goals
Many strategies contribute to other social, economic and environmental goals while reducing GHGs
Some strategies have significant equity implications that should be examined and addressed
25
Next Steps
Regional / state applications
• Regionally tailored strategy packages
• Climate action implementation
Continuing research
• Further analyses of individual strategies / bundles− Sensitivity to various parameters
− Vehicle conditions / traffic flow modeling
− Interactions with pricing
• Interactions with fuel and vehicle technology advancements
• Sub-national analyses
• Pilot regional assessments